Detection of bacterial signaling molecules in liquid or gaseous environments.

The detection of bacterial signaling molecules in liquid or gaseous environments has been occurring in nature for billions of years. More recently, man-made materials and systems has also allowed for the detection of small molecules in liquid or gaseous environments. This chapter will outline some examples of these man-made detection systems by detailing several acoustic-wave sensor systems applicable to quorum sensing. More importantly though, a comparison will be made between existing bacterial quorum sensing signaling systems, such as the Vibrio harveyi two-component system and that of man-made detection systems, such as acoustic-wave sensor systems and digital communication receivers similar to those used in simple cell phone technology. It will be demonstrated that the system block diagrams for either bacterial quorum sensing systems or man-made detection systems are all very similar, and that the established modeling techniques for digital communications and acoustic-wave sensors can also be transformed to quorum sensing systems.

Analogies between digital radio and chemical orthogonality as a method for enhanced analysis of molecular recognition events.

Acoustic wave biosensors are a real-time, label-free biosensor technology, which have been exploited for the detection of proteins and cells. One of the conventional biosensor approaches involves the immobilization of a monolayer of antibodies onto the surface of the acoustic wave device for the detection of a specific analyte. The method described within includes at least two immobilizations of two different antibodies onto the surfaces of two separate acoustic wave devices for the detection of several analogous analytes. The chemical specificity of the molecular recognition event is achieved by virtue of the extremely high (nM to pM) binding affinity between the antibody and its antigen. In a standard ELISA (Enzyme-Linked ImmunoSorbent Assay) test, there are multiple steps and the end result is a measure of what is bound so tightly that it does not wash away easily. The fact that this "gold standard" is very much not real time, masks the dance that is the molecular recognition event. X-Ray Crystallographer, Ian Wilson, demonstrated more than a decade ago that antibodies undergo conformational change during a binding event[1, 2]. Further, it is known in the arena of immunochemistry that some antibodies exhibit significant cross-reactivity and this is widely termed antibody promiscuity. A third piece of the puzzle that we will exploit in our system of acoustic wave biosensors is the notion of chemical orthogonality. These three biochemical constructs, the dance, antibody promiscuity and chemical orthogonality will be combined in this paper with the notions of in-phase (I) and quadrature (Q) signals from digital radio to manifest an approach to molecular recognition that allows a level of discrimination and analysis unobtainable without the aggregate. As an example we present experimental data on the detection of TNT, RDX, C4, ammonium nitrate and musk oil from a system of antibody-coated acoustic wave sensors.

Real-time detection of mesothelin in pancreatic cancer cell line supernatant using an acoustic wave immunosensor.

BACKGROUND: An acoustic wave immunosensor was developed to illustrate the viability of such devices in early detection of molecular cancer biomarkers. The methods described here involve a real-time, less invasive technique for detecting mesothelin, a protein that has been linked to pancreatic and ovarian cancer. METHODS: Antibodies were immobilized on the gold surface of the device via a self-assembled alkanethiol monolayer. Supernatant from two different pancreatic cancer cell-lines (PL1 and CAPAN2) containing an unknown concentration of mesothelin was tested for the protein by a flow-through analytical technique in three types of experiments. Binding of the mesothelin to the immobilized antibody layer caused a shift in the device's resonant frequency, which was correlated to the concentration of supernatant. A reference sensor was used to correct for frequency shifts caused by pressure or viscosity effects from the injection of the supernatant solution. RESULTS: Repeated experiments indicate that the sensors are capable of nanogram detection thresholds of mesothelin proteins at room temperature and in complex mixture. CONCLUSIONS: Acoustic wave device biosensors have the potential to become a valuable tool in screening for pancreatic as well as other types of cancers. The main features include real-time detection, high sensitivity, and ease of use.